Three-Dimensional Vertical Memory

ABSTRACT

In a shared three-dimensional vertical memory (3D-M v ), each horizontal address line comprises at least two regions: a lightly-doped region and a low-resistivity region. The lightly-doped region is formed around selected memory holes and shared by a plurality of low-leakage memory cells. The low-resistivity region forms a conductive network to reduce the resistance of the horizontal address line.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priorities from Chinese Patent Application 201810518263.X, filed on May 27, 2018; Chinese Patent Application 201810537891.2, filed on May 30, 2018; Chinese Patent Application 201810542880.3, filed on May 30, 2018; Chinese Patent Application 201810619764.7, filed on Jun. 14, 2018; Chinese Patent Application 201810674263.9, filed on Jun. 26, 2018, in the State Intellectual Property Office of the People's Republic of China (CN), the disclosure of which are incorporated herein by references in its entireties.

BACKGROUND 1. Technical Field of the Invention

The present invention relates to the field of integrated circuit, and more particularly to three-dimensional memory.

2. Prior Art

Three-dimensional vertical memory (3D-M_(v)) is a monolithic semiconductor memory. It comprises a plurality of vertical memory strings disposed side-by-side above (or, on) a semiconductor substrate. Each memory string comprises a plurality of vertically stacked memory cells. Because its memory cells are formed in a three-dimensional (3-D) space, the 3D-M_(v) has a large storage density and a low storage cost.

FIGS. 1A-1B disclose the overall structure of a conventional 3D-M_(v) (prior art). FIG. 1A is its cross-sectional view. It comprises a substrate circuit 0K, horizontal address lines 8 a-8 h, memory holes 2 a-2 d, programmable layers 6 a-6 d, vertical address lines 4 a-4 d and memory cells 1 aa-1 ha . . . . The substrate circuit 0K is formed on a semiconductor substrate 0. The horizontal address lines 8 a-8 h are interleaved with insulating layers 5 a-5 g above the substrate circuit 0K. The memory holes 2 a-2 d penetrate through the horizontal address lines 8 a-8 h and the insulating layers 5 a-5 g. The programmable layers 6 a-6 d cover the sidewalls of the memory holes 2 a-2 d. The vertical address lines 4 a-4 d is formed in the remaining spaces of the memory holes 2 a-2 d. The memory cells 1 aa-1 ha . . . are formed at the intersections of the horizontal address lines 8 a-8 h and the vertical address lines 4 a-4 d. Among them, all memory cells 1 aa-1 ha coupled to a same vertical address line 4 a form a memory string 1A.

FIG. 1B is a top view of a horizontal address line 8 a (prior art). The horizontal address line (also known as horizontal conductive plate) 8 a is a horizontal conductive plate with finite dimensions. After penetrating through the horizontal address line 8 a, the memory holes 2 a-2 h have their sidewalls covered by the programmable layer 6 a-6 h, before being filled with conductive materials to form the vertical address lines (also known as vertical conductive lines) 4 a-4 h. As before, the memory cells 1 aa-1 ah are formed at the intersections of the horizontal address line 8 a and the vertical address lines 4 a-4 h.

FIG. 1C is a symbol of the memory cell 1. The memory cell 1 comprises a programmable layer 12 and a diode 14. The resistance of the programmable layer 12 can be changed by at least an electrical programming signal. The diode 14 has two terminals: a positive terminal (also known as anode) 1+ and a negative terminal (also known as cathode) 1−. In general, a diode 14 favors current flow from its anode 1+ to its cathode 1−, but not the opposite. Technically, a diode is any two-terminal device with the following characteristics: when the applied voltage has its magnitude smaller than the read voltage V_(R) or its polarity opposite to the read voltage V_(R), the electrical resistance of the diode 14 is substantially larger than the read resistance V_(R) (i.e. the electrical resistance when the applied voltage is equal to the read voltage V_(R)). In other patents or technical papers, the diode 14 in a 3D-M_(v) is also referred to as selector, steering element, quasi-conductive layer, or other names. In this specification, these names have the same meaning.

The diode 14 is preferably a built-in P-N junction diode or Schottky diode formed naturally between the horizontal address line 8 a and the vertical address line 4 a. A built-in diode means that no separate diode layer is needed. To reduce the reverse leakage current and improve the reverse breakdown voltage of the diode 14, both the P-N junction diode and the Schottky diode preferably comprise a lightly-doped region. For example, the P-N junction diode preferably has a P+/N−/N+structure, the Schottky diode preferably has a metal/N−/N+structure. In both diode structures, the lightly-doped region is an N− layer and has a thickness ranging from tens of nanometers to tens of microns. Throughout this specification, the lightly-doped region could comprise an N− semiconductor material, an intrinsic (i−) semiconductor material, a P− semiconductor material, or a combination thereof.

FIG. 1D is a circuit schematic of a memory array 10 a (prior art). It comprises word lines 8 a-8 h, bit lines 4 a-4 h and memory cells 1 aa-1 ah . . . . Within a memory array 10 a, all word lines 8 a-8 h and all bit lines 4 a-4 h are continuous; and, they are not shared with any adjacent memory array(s). In this example, the word lines 8 a-8 h are coupled with the anodes 1+ of the diodes 14 in the memory cells 1 aa-1 ah, while the bit lines 4 a-4 h are coupled with the cathodes 1− of the diodes in the memory cells 1 aa-1 ah. During read, a read voltage V_(R) is applied to a selected one of the word lines, and the information stored in a memory cell(s) is read out from an associated bit line(s). Note that all unprogrammed memory cells 1 aa-1 ah . . . in a conventional semiconductor memory have similar physical structures. When the programmed memory cells store the same digital information (i.e. in the same digital state), they have similar electrical (e.g. current-voltage) characteristics.

FIG. 1E shows the structure of a memory cell 1 aa whose memory hole 2 a comprises a lightly-doped region 4 a′ (prior art). The anode 1+ of the diode 14 is the horizontal address line 8 a, while its cathode 1− is the vertical address line 4 a. The anode 1+ comprises at least a P+ semiconductor material (for the P-N junction diode) or at least a metallic material (for the Schottky diode), while the cathode 1− comprises at least a N− layer 4 a′ and N+ layer 4 a. Because both N− and N+ layers 4 a′, 4 a are formed inside the memory hole 2 a, the diameter D of the memory hole 2 a is equal to the sum of the diameter d of the vertical address line 4 a, twice the thickness T of the N− layer 4 a′ and twice the thickness t of the programmable layer 6 a (i.e. D=d+2T+2t). As the thickness T of the N− layer 4 a′ ranges from tens of nanometers to tens of microns, the diameter D of the memory hole 2 a is large. This leads to a low storage density and a high storage cost.

OBJECTS AND ADVANTAGES

It is a principle object of the present invention to provide a 3D-M_(v) with a large storage capacity.

It is a further object of the present invention to provide a 3D-M_(v) with a low storage cost.

It is a further object of the present invention to provide a 3D-M_(v) with smaller memory holes.

It is a further object of the present invention to provide a 3D-M_(v) with denser memory holes.

In accordance with these and other objects of the present invention, the present invention discloses several improved three-dimensional vertical memories (3D-M_(v)).

SUMMARY OF THE INVENTION

To minimize the diameter of the memory hole, the present invention discloses a two-region 3D-M_(v). Different from prior art of FIG. 1E, the lightly-doped region of the diode in the preferred two-region 3D-M_(v) is disposed outside the memory hole. Because the memory hole comprises only the vertical address line and the programmable layer, its diameter D is smaller. To be more specific, the horizontal address line of the preferred two-region 3D-M_(v) comprises at least two regions: a first region and a second region. The first region is a lightly-doped region surrounding the memory hole. It comprises at least a lightly-doped semiconductor material which would reduce the reverse leakage current and improve the reverse breakdown voltage of the memory cells. The second region is a low-resistivity region outside the first region. It comprises at least a conductive material whose resistivity is lower than that of the lightly-doped region. The low-resistivity region lowers the resistance of the horizontal address line and shortens the access time of the 3D-M_(v).

To reduce the spacing between the memory holes, the present invention further discloses a shared 3D-M_(v). It is an improvement over the two-region 3D-M_(v) with each lightly-doped region shared by a plurality of memory cells. To be more specific, the horizontal address line of the preferred shared 3D-M_(v) comprises at least two regions: a first lightly-doped region and a second low-resistivity region. Each lightly-doped region comprises a plurality of memory cells, which are formed at the intersections of the lightly-doped region and the vertical address lines. Because the memory cells in the lightly-doped region have a small reverse leakage current, these memory cells are referred to as leakage memory cells. On the other hand, the conductive material in the low-resistivity region forms a conductive network in the horizontal address line. It provides a low-resistance current-flowing path. This ensures a short access time and a small programming voltage.

Relative to the low-leakage memory cells in the lightly-doped region, the memory cells formed at the intersections of the low-resistivity region and the vertical address lines have a larger reverse leakage current and therefore, are referred to as high-leakage memory cells. Although a memory array of the preferred shared 3D-M_(v) could include both low-leakage and high-leakage memory cells at the same time, as long as the total number of the high-leakage memory cells is far smaller than that of the low-leakage memory cells, the performance of the preferred shared 3D-M_(v) would not be compromised.

The present invention discloses several preferred embodiments of the shared 3D-M_(v)'s. In the first preferred embodiment, the memory cells are formed in both lightly-doped and low-resistivity regions and have the same areal density (i.e. the number of memory cells per unit area on the horizontal address line). As long as the total area of the lightly-doped region is much larger than that of the low-resistivity region, this preferred embodiment can function correctly. In this preferred embodiment, the lightly-doped region has a rectangular shape. The second preferred embodiment is similar to the first preferred embodiment except that the lightly-doped region has a hexagonal shape. It should be apparent to those skilled in the art that the lightly-doped region could take other geometric shapes.

In the third preferred embodiment, the areal density of the high-leakage memory cells is smaller than that of the low-leakage memory cell. This would improve the performance of the 3D-M_(v). In the fourth preferred embodiment, no memory holes penetrate through the low-resistivity region. Because only the lightly-doped region comprises memory cells while the low-resistivity region does not comprise any memory cells, the memory array comprises only low-leakage memory cells, but no high-leakage memory cells. This would further improve the performance of the 3D-M_(v).

There is a major difference between the preferred shared 3D-M_(v) and a conventional semiconductor memory. In the conventional semiconductor memory, all unprogrammed memory cells (e.g. state ‘0’) have similar physical structures, while the programmed memory cells storing the same digital information (i.e. in the same digital state, e.g. state ‘1’) have similar electrical characteristics. In the preferred shared 3D-M_(v), even if they store the same digital information, the low-leakage memory cell and high-leakage memory cell have different electrical characteristics: the resistance of the high-leakage memory cell (e.g. state ‘1’) is smaller than that of the low-leakage memory cell (e.g. state ‘1’); and, the resistance of the low-leakage memory cell (e.g. state ‘1’) is smaller than that of the unprogrammed memory cell (e.g. state ‘0’).

Accordingly, the present invention discloses a three-dimensional vertical memory (3D-M_(v)), comprising: a semiconductor substrate including a substrate circuit; a plurality of horizontal address lines above said substrate circuit; a plurality of memory holes penetrating through said horizontal address lines; a plurality of programmable layers covering the sidewalls of said memory holes; a plurality of vertical address lines formed in said memory holes; wherein each of said horizontal address lines comprises at least first and second regions, with said first region having a higher resistivity than said second region.

The present invention further discloses another three-dimensional vertical memory (3D-M_(v)), comprising: a semiconductor substrate including a substrate circuit; a plurality of horizontal address lines above said substrate circuit; a plurality of memory holes penetrating through said horizontal address lines; a plurality of programmable layers covering the sidewalls of said memory holes; a plurality of vertical address lines formed in said memory holes; wherein each of said horizontal address lines comprises at least a first region surrounding selected ones of said vertical address lines, said first region comprising at least a lightly-doped semiconductor material.

The present invention further discloses a semiconductor memory, comprising: a plurality of first-state memory cells including at least a first-state memory cell; a plurality of second-state memory cells including at least a low-leakage memory cell and at least a high-leakage memory cell; an address line coupling said first-state memory cell, said low-leakage memory cell and said high-leakage memory cell; wherein said high-leakage memory cell has a smaller resistance than said low-leakage memory cell; and, said low-leakage memory cell has a smaller resistance than said first-state memory cell.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a z-x cross-sectional view of a conventional 3D-M_(v) along the cutline A-A′ of FIG. 1B (prior art); FIG. 1B is an x-y top view of its horizontal address line 8 a (prior art); FIG. 1C is a symbol representing a memory cell; FIG. 1D is a circuit schematic of a memory array of the conventional 3D-M_(v) (prior art); FIG. 1E is a z-x cross-sectional view of a memory cell whose memory hole comprises a lightly-doped region (prior art).

FIG. 2 is a z-x cross-sectional view of a preferred two-region 3D-M_(v) memory cell.

FIG. 3AA is a z-x cross-sectional view of a first preferred embodiment of the two-region 3D-M_(v) memory cell; FIG. 3AB is a symbol representing the memory cell of FIG. 3AA; FIG. 3BA is a z-x cross-sectional view of a second preferred embodiment of the two-region 3D-M_(v) memory cell; FIG. 3BB is a symbol representing the memory cell of FIG. 3BA.

FIG. 4A is an x-y top view of a horizontal address line 8 a of the preferred two-region 3D-M_(v); FIG. 4B is a z-x cross-sectional view of two neighboring memory cells of the preferred two-region 3D-M_(v).

FIG. 5A is a z-x cross-sectional view of a first preferred shared 3D-M_(v) along the cutline B-B′ of FIG. 5B; FIG. 5B is an x-y top view of its horizontal address line 8 a; FIG. 5CA is a circuit schematic of a memory array of the first preferred shared 3D-M_(v) which uses the memory cell of FIGS. 3AA-3AB; FIG. 5CB is a circuit schematic of a memory array of the first preferred shared 3D-M_(v) which uses the memory cell of FIGS. 3BA-3BB.

FIGS. 6A-6D are z-x cross-sectional views of the first preferred shared 3D-M_(v) at four manufacturing steps.

FIG. 7A is a z-x cross-sectional view of a second preferred shared 3D-M_(v) along the cutline C-C of FIG. 7B; FIG. 7B is an x-y top view of its horizontal address line 8 a; FIG. 7CA is a circuit schematic of a memory array of the second preferred shared 3D-M_(v) which uses the memory cell of FIGS. 3AA-3AB; FIG. 7CB is a circuit schematic of a memory array of the second preferred shared 3D-M_(v) which uses the memory cell of FIGS. 3BA-3BB.

FIGS. 8A-8D are x-y top views of the horizontal address lines 8 a in four preferred embodiments of the preferred shared 3D-M_(v)'s.

It should be noted that all the drawings are schematic and not drawn to scale. Relative dimensions and proportions of parts of the device structures in the figures have been shown exaggerated or reduced in size for the sake of clarity and convenience in the drawings. The same reference symbols are generally used to refer to corresponding or similar features in the different embodiments.

Throughout the present invention, the phrase “on the substrate” means the active elements of a circuit are formed on the surface of the substrate, although the interconnects between these active elements are formed above the substrate; the phrase “above the substrate” means the active elements are formed above the substrate and do not touch the substrate. The symbol “/” means a relationship of “and” or “or”.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

Those of ordinary skills in the art will realize that the following description of the present invention is illustrative only and is not intended to be in any way limiting. Other embodiments of the invention will readily suggest themselves to such skilled persons from an examination of the within disclosure.

To minimize the diameter of the memory hole, the present invention discloses a two-region 3D-M_(v). Different from prior art of FIG. 1E, the lightly-doped region of the diode in the preferred two-region 3D-M_(v) is disposed outside the memory hole. Because the memory hole comprises only the vertical address line and the programmable layer, its diameter D is smaller. Details of the preferred two-region 3D-M_(v)'s are disclosed in FIGS. 2-4B.

Referring now to FIG. 2, a memory cell 1 aa of a preferred two-region 3D-M_(v) is shown. It comprises a horizontal address line 8 a, a memory hole 2 a penetrating through the horizontal address line 8 a, a programmable layer 6 a covering the sidewall of the memory hole 2 a, and a vertical address line 4 a in the memory hole 2 a. The programmable layer 6 a could be one-time programmable (OTP), multiple-time programmable (MTP) or re-programmable. For an OTP memory, the programmable layer 6 a comprises an antifuse layer. Examples of the antifuse material include silicon oxide layer, silicon nitride layer, or a combination thereof. For an MTP or re-programmable memory, the programmable layer 6 a is a re-writable layer. Examples of the re-writable material include resistive RAM (RRAM) material, phase-change memory (PCM) material, conductive-bridge RAM (CBRAM) material, magnetic RAM (MRAM) material and other materials. The thickness t of the programmable layer 6 a ranges from 1 nm to 200 nm.

The horizontal address line 8 a comprises two regions: a first region 9 a* and a second region 7 a*. The first region 9 a* is a lightly-doped region surrounding the memory hole 2 a. It comprises at least a lightly-doped semiconductor material, e.g. N− semiconductor material, P− semiconductor material, or intrinsic semiconductor material. The thickness T of the lightly-doped region 9 a* ranges from tens of nanometers to tens of microns. The second region 9 a* is a low-resistivity region outside the lightly-doped region 9 a*. It comprises at least a conductive material whose resistivity is lower than that of the lightly-doped region 9 a*. Examples of the conductive material include heavily-doped semiconductor material (e.g. N+ semiconductor material, P+ semiconductor material, semiconductor material doped with metal, etc.), and metallic material (e.g. metal, metal compound, etc.). The presence of the lightly-doped region 9 a* reduces the reverse leakage current and improves the reverse breakdown voltage of the memory cell 1 aa, whereas the presence of the low-resistivity region 7 a* lowers the resistance of the horizontal address line 8 a and shortens the access time of the 3D-M_(v).

Because the lightly-doped region 9 a* in the memory cell 1 aa is disposed outside the memory hole 2 a, the diameter D of the memory hole 2 a is equal to the sum of the diameter d of the vertical address line 4 a and twice the thickness t of the programmable layer 6 a (i.e. D=d+2t). As a result, the diameter D of the memory hole 2 a is much smaller than that of FIG. 1E (prior art).

FIGS. 3AA-3AB disclose a first preferred embodiment of the two-region 3D-M_(v) memory cell 1 aa. In this first preferred embodiment, the vertical address line 4 a comprises P+ semiconductor material or metallic material, while the lightly-doped region 9 a* of the horizontal address line 8 a comprises at least an N− (or, i−) semiconductor material and the low-resistivity region 7 a* comprises at least an N+ semiconductor material (FIG. 3AA). Accordingly, the vertical address line 4 a is coupled to the anode of the diode 14, whereas the horizontal address line 8 a is coupled to the cathode of the diode 14 (FIG. 3AB).

FIGS. 3BA-3BB disclose a second preferred embodiment of the two-region 3D-M_(v) memory cell 1 aa. In this second preferred embodiment, the vertical address line 4 a comprises at least an N+ semiconductor material, while the lightly-doped region 9 a* of the horizontal address line 8 a comprises at least an N− (or, i−) semiconductor material and the low-resistivity region 7 a* comprises at least a P+ semiconductor material or metallic material (FIG. 3BA). Accordingly, the vertical address line 4 a is coupled to the cathode of the diode 14, whereas the horizontal address line 8 a is coupled to the anode of the diode 14 (FIG. 3BB).

FIGS. 4A-4B disclose an overall structure of a preferred two-region 3D-M_(v) 30. FIG. 4A is a top view of a horizontal address line 8 a. The memory holes 2 a-2 h penetrate through the horizontal address line 8 a. Inside the memory holes 2 a-2 h, their sidewalls are covered with the programmable layers 6 a-6 h. Outside the memory holes 2 a-2 h, the lightly-doped regions 9 a*-9 h* surround the memory holes 2 a-2 h. Further outside the lightly-doped regions 9 a*-9 h*, the remaining areas of the horizontal address line 8 a are the low-resistivity region 7 a*.

FIG. 4B shows two neighboring memory cells 1 aa, 1 ab in the preferred two-region 3D-M_(v) 30. Each of the memory cells 1 aa, 1 ab has the structure shown in FIG. 2. Between the two memory cells 1 aa, 1 ab, there is a low-resistivity region 7 a*. The spacing S between two memory holes 2 a, 2 b is equal to the sum of twice the thickness T of the lightly-doped regions 9 a*, 9 b* and the thickness T′ of the low-resistivity region 7 a* (i.e. S=2T+T). Because the thickness T of the lightly-doped regions 9 a*, 9 b* ranges from tens of nanometers to tens of microns, the spacing S in this preferred two-region 3D-M_(v) 30 is large.

To reduce the spacing between the memory holes, the present invention further discloses a shared 3D-M_(v). It is an improvement over the two-region 3D-M_(v) with each lightly-doped region shared by a plurality of memory cells. In the following figures, FIGS. 5A-6D disclose a first preferred shared 3D-M_(v), FIGS. 7A-7CB disclose a second preferred shared 3D-M_(v), and FIGS. 8A-8D disclose several other preferred embodiments.

Referring now to FIGS. 5A-5CB, a first preferred shared 3D-M_(v) 20 is shown. It comprises a plurality of vertically stacked horizontal address lines 8 a-8 h, a plurality of memory holes 2 a-2 d penetrating through the horizontal address lines 8 a-8 h, a plurality of programmable layers 6 a-6 d covering the sidewalls of the memory holes 2 a-2 d, and a plurality of vertical address lines 4 a-4 d formed inside the memory holes 2 a-2 d (FIG. 5A). The preferred shared 3D-M_(v) 20 is divided into at least two sections: a first lightly-doped section 9 and a second low-resistivity section 7. All horizontal address lines 8 a-8 h that fall within the first lightly-doped section 9 comprises at least a lightly-doped semiconductor material, while all horizontal address lines 8 a-8 h that fall within the second low-resistivity section 7 comprises at least a low-resistivity material. Accordingly, the horizontal address lines 8 a-8 h comprise at least two regions: first lightly-doped regions 9 a-9 h and second low-resistivity regions 7 a-7 h.

For each horizontal address line (e.g. 8 a), its lightly-doped region 9 a is shared by the memory cells 1 aa, 1 ab, 1 ae, 1 af (FIG. 5B). Because they are formed at the intersections of the lightly-doped region 9 a and the vertical address lines 4 a, 4 b, 4 e, 4 f, these memory cells 1 aa, 1 ab, 1 ae, 1 af have small reverse leakage currents and therefore, are referred to as low-leakage memory cells. Whereas, the memory cells 1 ac, 1 ag formed at the intersections of the low-resistivity region 7 a and vertical address lines 4 c, 4 g have large reverse leakage currents and therefore, are referred to as high-leakage memory cells. On the other hand, the conductive material in the low-resistivity region 7 a forms a conductive network in the horizontal address line 8 a. It provides a low-resistance current-flowing path. This ensures a short access time and a small programming voltage for the preferred shared 3D-M_(v) 20.

FIG. 5CA is a circuit schematic of a memory array 20 a of the first preferred shared 3D-M_(v) 20 which uses the memory cell of FIGS. 3AA-3AB. Each open symbol (i.e. with an open triangle) represents a low-leakage memory cell (e.g. 1 aa), while each solid symbol (i.e. with a solid triangle) represents a high-leakage memory cell (e.g. 1 ac). As indicated in FIG. 3AB, the vertical address lines 4 a-4 h are coupled to the anodes of the diodes in the memory cells 1 aa-1 ah . . . and act as word lines, whereas the horizontal address lines 8 a-8 h are coupled to the cathodes of the diodes in the memory cells 1 aa-1 ah . . . and act as bit lines. During read, a read voltage V_(R) is applied on a selected one (e.g. 4 a) of the vertical address lines (word lines) 4 a-4 h while all other vertical address lines 4 b-4 h are grounded. The information stored in the memory cells 1 aa-1 ha is read out by sensing the voltage changes on the horizontal address lines (bit lines) 8 a-8 h. In this preferred embodiment, the horizontal address lines (bit lines) 8 a-8 h are coupled to the sense amplifiers (not shown in this figure for reason of simplicity).

FIG. 5CB is a circuit schematic of a memory array 20 a of the first preferred shared 3D-M_(v) 20 which uses the memory cell of FIGS. 3BA-3BB. As indicated in FIG. 3BB, the vertical address lines 4 a-4 h are coupled to the cathodes of the diodes in the memory cells 1 aa-1 ah . . . and act as bit lines, whereas the horizontal address lines 8 a-8 h are coupled to the anodes of the diodes and act as word lines. During read, a read voltage V_(R) is applied on a selected one (e.g. 8 a) of the horizontal address lines (word lines) 8 a-8 h while all other horizontal address lines 8 b-8 h are grounded. The information stored in the memory cells 1 aa-1 ah is read out by sensing the voltage changes on the vertical address lines (bit lines) 4 a-4 h. In this preferred embodiment, the vertical address lines (bit lines) 4 a-4 h are coupled to the sense amplifiers (not shown in this figure for reason of simplicity).

In the conventional semiconductor memory, all unprogrammed memory cells (e.g. in state ‘0’) have similar physical structures, while the programmed memory cells storing the same digital information (i.e. in the same digital state, e.g. in state ‘1’) have similar electrical characteristics. On the other hand, in the preferred shared 3D-M_(v) 20, even if they store the same digital information, the low-leakage memory cell 1 aa and high-leakage memory cell lac have different electrical characteristics: the resistance of the high-leakage memory cell (e.g. in state ‘1’) 1 ac is lower than that of the low-leakage memory cell (e.g. in state ‘1’) 1 aa; and, the resistance of the low-leakage memory cell (e.g. in state ‘1’) is smaller than that of the unprogrammed memory cell (e.g. in state ‘0’).

FIGS. 6A-6D show four manufacturing steps of the first preferred shared 3D-M_(v) 20. The manufacturing steps for the substrate circuit 0K is well known to those skilled in the art and will not be described here. After the top of the substrate circuit 0K is planarized, a first lightly-doped layer 12 a is deposited thereon. This lightly-doped layer 12 a has a thickness ranging from 5 nm to 200 nm. It could be doped with N− semiconductor material, P− semiconductor material, or not doped at all (i.e. an intrinsic semiconductor layer). Then a first insulating layer 5 a is deposited on the lightly-doped layer 12 a. The insulating layer 5 a has a thickness ranging from 5 nm to 200 nm. It could comprise silicon oxide, silicon nitride, other insulating material, or a combination thereof. This process is then repeated for the remaining lightly-doped layers 12 b-12 h and insulating layers 5 b-5 g (FIG. 6A).

After forming the lightly-doped layers 12 a-12 h, a first photolithography step is performed on its top surface. A photo-resist layer (not shown in FIG. 6B for reason of simplicity) covers the low-resistivity section 9 but not the lightly-doped section 7. Then an ion-implant step is carried out. The implanted ions could be N+ ions, P+ ions, or metal ions. After the ion-implant step, the regions 7 a-7 h in the lightly-doped layers 12 a-12 h become heavily doped and have a low resistivity (FIG. 6B).

Next, a second photolithography step is performed. The lightly-doped layers 12 a-12 h are etched to form the horizontal address lines 8 a-8 h and associated structures (FIG. 6C). Then a third photolithography step is performed. The memory holes 2 a-2 d are etched through the horizontal address lines 8 a-8 h (FIG. 6D). This is followed by the formation of the programmable layers 6 a-6 d and the vertical address lines 4 a-4 d (FIG. 5A). Since the above manufacturing steps are similar to those of 3D-NAND, their details will not be described here. Overall, the preferred shared 3D-M_(v) 20 has a simple physical structure and requires a simple manufacturing process.

In one preferred manufacturing method, the lightly-doped layers 12 a-12 h and insulating layers 5 a-5 g are preferably deposited continuously and without any interruption (FIG. 6A). These layers are deposited inside a single deposition tool without any non-depositing steps (e.g. photolithography steps) in-between. As a result, wafers do not need to be taken out from the deposition tool during the deposition process. Because planarization is well kept during these deposition steps, tens to hundreds of lightly-doped layers can be deposited together (eight layers are shown in FIG. 6A). In other words, the preferred shared 3D-M_(v) 20 could comprise tens to hundreds of levels of horizontal address lines. For this preferred method, the low-resistivity regions 7 a-7 h in the horizontal address lines 8 a-8 h are formed in a single ion-implant step.

In another preferred manufacturing method, the low-resistivity regions 7 a-7 h are formed in separate steps (not shown in FIGS. 6A-6D for reason of simplicity). For example, a lithography step is performed after the formation of the first lightly-doped layer 12 a. Then an ion-implant step (or, a silicidation step) is carried out to lower the resistivity of a selected region 7 a in the first lightly-doped layer 12 a. This is followed by the formation of the first insulating layer 5 a and the second lightly-doped layer 12 b. After that, another lithography step is performed and another ion-implant step (or, another silicidation step) is carried out to lower the resistivity of another selected region 7 b in the second lightly-doped layer 12 b. The above steps are repeated for other lightly-doped layers 12 c-12 h. One advantage of this method is that the low-resistivity regions (e.g. 7 a, 7 b) can be formed at different locations in different lightly-doped layers (e.g. 12 a, 12 b). They do not need to overlap.

Referring now to FIGS. 7A-7CB, a second preferred shared 3D-M_(v) 20 is disclosed. This preferred embodiment is similar to that in FIGS. 5A-5CB except that there is no memory hole in the low-resistivity section 7 (FIG. 7A). Accordingly, only the lightly-doped region 9 a comprises memory cells 1 aa, 1 ab, 1 ad-1 af, 1 ah, while the low-resistivity region 7 a does not comprise any memory cells (FIG. 7B). This is further illustrated in FIGS. 7CA-7CB. The memory array 20 a only comprises low-leakage memory cells 1 aa, 1 ab, 1 ad-1 af, 1 ah (represented by open symbols), but does not comprise any high-leakage memory cells. As a result, this preferred shared 3D-M_(v) 20 has a robust read-write performance.

Although a memory array 20 a of the preferred shared 3D-M_(v) 20 could include both low-leakage memory cells 1 aa-1 ha . . . and high-leakage memory cells 1 ac-1 hc . . . at the same time, as long as the total number of the high-leakage memory cells 1 ac-1 hc . . . is far smaller than the low-leakage memory cells 1 aa-1 ha . . . , the performance of the preferred shared 3D-M_(v) 20 would not be compromised. Accordingly, the present invention further discloses several preferred embodiments of the shared 3D-M_(v)'s in FIGS. 8A-8D. In these figures, each dot represents a memory hole. For reason of simplicity, the internal structures of the memory hole are not shown.

The preferred embodiment of FIG. 8A corresponds to FIGS. 5A-5CB. The low-leakage memory cells 2 x are formed in the lightly-doped region 9 a, while the high-leakage memory cells 2 y are formed in the low-resistivity region 7 a. Both low-leakage memory cells 2 x and high-leakage memory cells 2 y have the same areal density. As long as the total area of the lightly-doped region 9 a is much larger than that of the low-resistivity region 7 a, this preferred embodiment can function correctly. In FIG. 8A, the lightly-doped region 9 a has a rectangular shape. Whereas, the lightly-doped region 9 a in FIG. 8B has a hexagonal shape. It should be apparent to those skilled in the art that the lightly-doped region 9 a could take other geometric shapes.

In the preferred embodiment of FIG. 8C, the areal density of the low-leakage memory cells 2 x remains same as that of FIG. 8A, but the areal density of the high-leakage memory cells 2 y is lower than that of FIG. 8A. Compared to FIG. 8A, it has fewer high-leakage memory cells 2 y. This would improve the performance of the preferred shared 3D-M_(v) 20. The preferred embodiment of FIG. 8D corresponds to FIGS. 7A-7CB. Because only the lightly-doped region 9 a comprises memory cells while the low-resistivity region 7 a does not comprise any memory cells, the memory array 20 a comprises only low-leakage memory cells 2 x, but no high-leakage memory cells. This would further improve the read-write performance of the preferred shared 3D-M_(v) 20.

While illustrative embodiments have been shown and described, it would be apparent to those skilled in the art that many more modifications than that have been mentioned above are possible without departing from the inventive concepts set forth therein. The invention, therefore, is not to be limited except in the spirit of the appended claims. 

1. A three-dimensional vertical memory (3D-M_(v)), comprising: a semiconductor substrate including a substrate circuit; a plurality of horizontal address lines above said substrate circuit; a plurality of memory holes penetrating through said horizontal address lines; a plurality of programmable layers covering the sidewalls of said memory holes; a plurality of vertical address lines formed in said memory holes; wherein each of said horizontal address lines comprises at least first and second regions, with said first region having a higher resistivity than said second region.
 2. The 3D-M_(v) according to claim 1, wherein: said first region comprises at least a lightly-doped semiconductor material; and, said second region comprises at least a heavily-doped semiconductor material or a metallic material.
 3. The 3D-M_(v) according to claim 1, wherein the total area of said first region is larger than said second region.
 4. The 3D-M_(v) according to claim 1, wherein said memory holes penetrate through said horizontal address lines in said first and second regions.
 5. The 3D-M_(v) according to claim 1, wherein a plurality of memory cells formed at the intersections of said horizontal address lines and said vertical address lines, with the areal density of said memory cells in said first region larger than said second region.
 6. The 3D-M_(v) according to claim 1, wherein said memory holes penetrate through said horizontal address lines in said first region; no memory hole penetrates through said horizontal address lines in said second region.
 7. The 3D-M_(v) according to claim 1, wherein said programmable layer is one-time programmable, multiple-time programmable, or re-programmable.
 8. A three-dimensional vertical memory (3D-M_(v)), comprising: a semiconductor substrate including a substrate circuit; a plurality of horizontal address lines stacked above said substrate circuit; a plurality of memory holes penetrating through said horizontal address lines; a plurality of programmable layers covering the sidewalls of said memory holes; a plurality of vertical address lines formed in said memory holes; wherein each of said horizontal address lines comprises at least a first region surrounding selected ones of said vertical address lines, said first region comprising at least a lightly-doped semiconductor material.
 9. The 3D-M_(v) according to claim 8, wherein each of said horizontal address lines comprises at least a second region outside said first region, with said first region having a higher resistivity than said second region.
 10. The 3D-M_(v) according to claim 9, wherein said second region comprises a heavily-doped semiconductor material or a metallic material.
 11. The 3D-M_(v) according to claim 9, wherein the total area of said first region is larger than said second region.
 12. The 3D-M_(v) according to claim 9, wherein said memory holes penetrate through said horizontal address line in said first and second regions.
 13. The 3D-M_(v) according to claim 9, wherein a plurality of memory cells formed at the intersections of said horizontal address lines and said vertical address lines, with the areal density of said memory cells in said first region larger than said second region.
 14. The 3D-M_(v) according to claim 9, wherein said memory holes penetrate through said horizontal address lines in said first region; no memory hole penetrates through said horizontal address lines in said second region.
 15. The 3D-M_(v) according to claim 8, wherein said programmable layer is one-time programmable, multiple-time programmable, or re-programmable.
 16. A semiconductor memory, comprising: a plurality of first-state memory cells including at least a first-state memory cell; a plurality of second-state memory cells including at least a low-leakage memory cell and at least a high-leakage memory cell; an address line coupling said first-state memory cell, said low-leakage memory cell and said high-leakage memory cell; wherein said high-leakage memory cell has a smaller resistance than said low-leakage memory cell; and, said low-leakage memory cell has a smaller resistance than said first-state memory cell.
 17. The semiconductor memory according to claim 16, further comprising: a semiconductor substrate including a substrate circuit; a plurality of horizontal address lines stacked above said substrate circuit; a plurality of memory holes penetrating through said horizontal address lines; a plurality of programmable layers covering the sidewalls of said memory holes; a plurality of vertical address lines formed in said memory holes; wherein each of said horizontal address lines comprises at least first and second regions, with said first region having a higher resistivity than said second region; wherein said low-leakage memory cell is formed at an intersection of said first region and a selected one of said vertical address lines; and, said high-leakage memory cell is formed at another intersection of said second region and another selected one of said vertical address lines.
 18. The semiconductor memory according to claim 17, wherein said first region comprises at least a lightly-doped semiconductor material; and, said second region comprises at least a heavily-doped semiconductor material or a metallic material.
 19. The semiconductor memory according to claim 17, wherein the total area of said first region is larger than said second region.
 20. The semiconductor memory according to claim 16, wherein said semiconductor memory is one-time programmable, multiple-time programmable, or re-programmable. 